Effects of the resistance plasmid R124 on the level of the OmpF outer membrane protein and on the response of Escherichia coli to environmental agents

The introduction of the F-like resistance plasmid R124 into an ompC mutant of Escherichia coli K12 conferred altered sensitivity to a wide range of inhibitory agents. Sensitivity to ampicillin, chloramphenicol, ethionine, copper ions, deoxycholate, two fatty acids and colicins L and M was decreased by the plasmid. In contrast the plasmid-bearing ompC derivatives were more sensitive than the plasmid-free ompC mutant to erythromycin, cetyltrimethylammonium bromide and phenol. Introduction of R124 into the ompC strain also decreased the level of the OmpF protein and some (but not all) of the changed sensitivities listed above clearly resulted from this outer membrane protein deficiency. The presence in the ompC mutant of R124 (rather than the more efficient introduction of the plasmid into variants of the ompC strain) led to at least most of the changes described above because those tested were accentuated by the presence of a copy mutant of R124 and reversed by plasmid curing.     

OmpC and OmpF are required for growth under hyperosmotic stress above pH 8 in Escherichia coli

AIMS: To investigate the requirement of outer membrane porins for osmotic adaptation at alkaline pH in Escherichia coli. METHODS AND RESULTS: Escherichia coli mutants deficient in ompC, ompF and both genes were constructed and the growth of these mutants was observed at alkaline pH. The growth rate of the mutant deficient in both ompC and ompF was slower than that of the wild type and mutants deficient in one of these genes under hyperosmotic stress at pHs above 8.0. The decreased rate was recovered when a cloned ompC was introduced to the mutant, but the growth recovery with a cloned ompF was partial. Such growth diminution was not observed at pHs below 8.0. CONCLUSION: OmpC and OmpF were shown to participate in hyperosmotic adaptation at alkaline pH in E. coli. SIGNIFICANCE AND IMPACT OF THE STUDY: This study is the first report to demonstrate that OmpC and OmpF are required for hyperosmotic adaptation at pHs above 8.0, but not below 8.0.     

Effect of outer membrane permeability on chemotaxis in Escherichia coli.

The relationship between outer membrane permeability and chemotaxis in Escherichia coli was studied on mutants in the major porin genes ompF and ompC. Both porins allowed passage of amino acids across the outer membrane sufficiently to be sensed by the methyl-accepting chemotaxis proteins, although OmpF was more effective than OmpC. A mutant deleted for both ompF and ompC, AW740, was almost completely nonchemotactic to amino acids in spatial assays. AW740 required greater stimulation with L-aspartate than did the wild type to achieve full methylation of methyl-accepting chemotaxis protein II. Induction of LamB protein allowed taxis to maltose but not to L-aspartate, which indicates that the maltoporin cannot rapidly pass aspartate. Salt taxis was less severely inhibited by the loss of porins than was amino acid taxis, which implies an additional mechanism of outer membrane permeability. These results show that chemotaxis can be used as a sensitive in vivo assay for outer membrane permeability to a range of compounds and imply that E. coli can regulate chemotactic sensitivity by altering the porin composition of the outer membrane.     

Copper sensitivity in an envelope mutant of Escherichia coli and its suppression by ColV, I-K94

A phage K3-resistant isolate from Escherichia coli P678-54 was devoid of both the OmpA and OmpC proteins but had high levels of the OmpF protein. Associated with these changes, the strain showed increased sensitivity to inhibition by detergents and greatly increased sensitivity to Cu²⁺. Introduction of the ColV, I-K94 plasmid into this mutant produced a derivative with markedly increased resistance to Cu²⁺ ions but unchanged detergent sensitivity. Analysis of membranes showed that the ColV, I-K94⁺ derivative had essentially no OmpF protein in its outer membrane. A ca 36 K outer membrane protein was present which resembled the OmpC protein in size and failure to dissociate in SDS at low temperature. It was distinct from the OmpC protein, however, in failing to allow either tetracycline uptake or the adsorption of T4-type phages. The possible significance of OmpF porin derepression (and its reversal by ColV, I-K94) for enterobacterial survival in aquatic situations is discussed.     

Regulatory mutations conferring constitutive synthesis of major outer membrane proteins (OmpC and OmpF) in Escherichia coli.

An ompB strain of Escherichia coli K-12 lacking major outer membrane proteins OmpC and OmpF was used to isolate a pair of mutants that have restored the ability to synthesize either OmpC or OmpF protein. These mutants were found to produce the respective proteins constitutively under the several conditions where the synthesis in the wild-type strain was markedly repressed; namely, in the absence of the ompB gene function, under restrictive medium conditions, or upon lysogenization with phage PA-2. The mutations ompCp1 and ompFp9 responsible for such synthesis were shown to be located in the close vicinity of the corresponding structural genes, ompC and ompF. Moreover, the mutations affect the expression of these genes in a cis-dominant fashion. Taken together with other evidence, it was suggested that ompCp1 and ompFp9 represent regulatory site mutations occurring at the promoter regions of ompC and ompF respectively. Relevance of these findings to the genetic control of outer membrane protein synthesis is discussed.     

Purification and characterization of the OmpR protein, a positive regulator involved in osmoregulatory expression of the ompF and ompC genes in Escherichia coli

The OmpR protein is a positive regulator involved in osmoregulatory expression of the ompF and ompC genes, which respectively code for major outer membrane proteins OmpF and OmpC of Escherichia coli. The OmpR protein has been purified to homogeneity from an overproducing strain harboring an ompR gene-carrying plasmid. Throughout the purification the OmpR protein behaved as a single entity. The molecular weight determined on sodium dodecyl sulfate-polyacrylamide gel, the total amino acid composition, and the NH2-terminal amino acid sequence of the purified protein were essentially the same as those deduced from the nucleotide sequence of the ompR gene. Molecular weight determination and cross-linking study on the native protein revealed that the purified protein exists as a monomer. The purified OmpR protein was specifically bound to the promoter regions of the ompC and ompF genes. Experiments with a series of upstream deletions of the ompC and ompF promoters revealed that the region upstream from the -35 region was indispensable for OmpR binding to both the ompC and the ompF promoters. Although it has been proposed that depending on the medium osmolarity the OmpR protein may exist in two alternative structures, which respectively regulate functioning of the ompC and the ompF promoters, the purified OmpR protein appeared to be homogeneous and interacted with both promoters to the same extent.     

Location of phosphorylation site and DNA-binding site of a positive regulator, OmpR, involved in activation of the osmoregulatory genes of Escherichia coli

The OmpR protein of Escherichia coli is a positive regulator involved in activation of the ompF and ompC genes which encode the major outer membrane proteins OmpF and OmpC, respectively. By employing recombinant DNA techniques, we isolated the N- and C-terminal halves of the OmpR molecule. From the results of biochemical analyses of these fragments, it was concluded that the N-terminal portion contains a site involved in phosphorylation by an OmpR-specific protein kinase EnvZ, whereas the C-terminal part possesses a DNA-binding site for the ompC and ompF promoters.     

Isolation of an ompC-like outer membrane protein gene from Salmonella typhi

We have isolated the structural gene for an outer membrane protein of Salmonella typhi, from a genomic library constructed in bacteriophage lambda 1059, using the Escherichia coli ompC gene as a heterologous probe. E. coli ompC codes for an outer membrane pore protein (porin) that is induced preferentially at high osmolarity and high temperature. The S. typhi ompC-like gene was subcloned in pBR322 and introduced into E. coli HB101 and into P678-54, a minicell-producing strain. In both strains it expressed a 38.5-kDa protein, which was incorporated into the outer membrane envelope and comigrated with an S. typhi outer membrane protein which was expressed both at low and high osmolarity in vivo.     

Phosphorylation of a bacterial activator protein, OmpR, by a protein kinase, EnvZ, results in stimulation of its DNA-binding ability

The Escherichia coli OmpR protein is an activator protein specific for the ompF and ompC genes, which respectively encode the outer membrane proteins, OmpF and OmpC. The EnvZ protein is a protein kinase specific for the OmpR protein. In this study, we compared the in vitro DNA-binding ability of the phosphorylated form of the OmpR protein with that of the non-phosphorylated form by means of non-denaturing gel retardation analysis and DNase I footprinting analysis. The results indicate that the phosphorylation of the OmpR protein results in stimulation of its in vitro DNA-binding ability as to both the ompF and ompC promoter DNAs.     

Genetic identification of the pore domain of the OmpC porin of Escherichia coli K-12.

We have isolated and characterized 31 mutations in the ompC gene which allow Escherichia coli to grow on maltotriose (Dex+) in the absence of the LamB and OmpF porins. These ompC(Dex) mutations include single-base-pair substitutions, small deletions, and small insertions. DNA sequence analysis shows that all of the alterations occur within the coding region for the first 110 amino acids of mature OmpC. The 26 independent point mutations repeatedly and exclusively alter residues R37, R74, and D105 of mature OmpC. In each case, a charged amino acid is changed to an uncharged residue. Biochemical and physiological tests suggest that these alterations increase the size of the pore channel. Starting with three different ompC(Dex) strains with alterations affecting R74, we isolated mutants that could grow on maltohexose (Hex+). These mutants each contained a second alteration in the ompC gene involving residues R37, D105, or R124. The combined effects on pore function of the two mutations appear to be additive. These experiments suggest that we have identified the important residues of OmpC peptide involved in pore function. On the basis of these mutations and general rules for membrane protein folding, a model for the topology of the OmpC protein is proposed.     

质粒在大肠杆菌对噬菌体抗性中的作用

The introduction of the ColV, I-K94 or R124 plasmid into Escherichia coli K12 resulted in resistance to certain phages. Derivatives of E. coli carrying the plasmid R124 and ColV, I-K94 were resistance to the phages T4, Mel comparing with the plasmid-free parent and the plasmid ColV, I-K94 conferred resistance to the phage Tull*. It suggested that an envelope change caused by the plasmids might be responsible for the resistance because most of the phages fell to absorb to the plasmid-bearing E. coli cells.     

Secretion into the culture medium of a foreign gene product from Escherichia coli: use of the ompF gene for secretion of human beta-endorphin.

The ompF gene codes for a major outer membrane protein of Escherichia coli. A plasmid was constructed in which the structural gene for human beta-endorphin is preceded by the upstream region of the ompF gene consisting of the promoter region and the coding regions for the signal peptide and the N terminus of the OmpF protein. When the plasmid was introduced into E. coli N99, and OmpF-beta-endorphin fused peptide was synthesized and secreted into the culture medium through both the cytoplasmic and outer membranes. The OmpF signal peptide was cleaved correctly during the secretion, indicating that the export of the fused protein across the cytoplasmic membrane was dependent on the signal peptide. The secretion into the culture medium was apparently selective. Neither beta-lactamase nor alkaline phosphatase (both are periplasmic proteins) appeared in the culture medium in significant amounts. The mode of passage of the fused peptide across the outer membrane is discussed.     

Yersinia pseudotuberculosis mutant OmpF porins with deletions of the external loops: genetic constructions design, expression, isolation and refolding

Yersinia pseudotuberculosis outer membrane (OM) recombinant mutant OmpF porins with deletions of the external loops L1, L6 and L8 were obtained using site-directed mutagenesis of the recombinant plasmid including ompF gene. Heterologeous expression of the mutant proteins was carried out in strain Rosetta of Escherichia coli (Novagen, USA), porins with the deletions were isolated from the inclusion bodies. Mutant proteins in oligomeric form were obtained as result of dialysis and ion-exchange chromatography. Spatial structure of the mutant proteins was demonstrated to have special features in comparison with that of the full-structured OmpF porin on the level of both secondary and tertiary structure. Lacking of the loops L1, L6 and L8 didn't affect the conductivity level of Y pseudotuberculosis porin channel as shown using bilayer lipid membrane (BLM) technique. Lacking of the loops mentioned above has a significant influence on the antigenic structure of the mutant porins as demonstrated with use of immunoblotting technique and ELISA.     

PhoE protein pore of the outer membrane of Escherichia coli K12 is a particularly efficient channel for organic and inorganic phosphate

This study was undertaken to investigate the proposed in vivo pore function of PhoE protein, an Escherichia coli K12 outer membrane protein induced by growth under phosphate limitation and to compare it with those of the constitutive pore proteins OmpF and OmpC. Appropriate mutant strains were constructed containing only one of the proteins PhoE, OmpF or OmpC, or none of these proteins at all. By measuring rates of nutrient uptake at low solute concentrations, the proposed pore function of PhoE protein was confirmed as the presence of the protein facilitates the diffusion of Pi through the outer membrane, such as a pore protein deficient strain behaves as a Km mutant. Comparison of the rates of permeation of Pi, glycerol 3-phosphate and glucose 6-phosphate through pores formed by PhoE, OmpF and OmpC proteins shows that PhoE protein is the most effective pore in facilitating the diffusion of Pi and phosphorus-containing compounds. The three types of pores were about equally effective in facilitating the permeation of glucose and arsenate. Possible reasons for the preference for Pi and Pi-containing solutes are discussed.